Anti-misplacement data line welding equipment

Abstract

The utility model discloses a kind of misplacement prevention data line welding equipment, including conveying mechanism, several jigs are installed on the conveying mechanism, the jig reaches in turn pull line station, cutting station, stripping station, and welding station, welding seat is equipped at alignment welding station, the welding seat is correspondingly installed with connector feeding mechanism;The jig includes jig body, wire slot is equipped on the jig body, the wire slot end portion is equipped with wire clamp fork one, rotatingly connected with pressure block one on jig body, torsional spring is equipped at rotating connection, pressure plate one is equipped above the moving channel of conveying mechanism, the pressure plate one is used to compress pressure block one tightly, the pressure plate one is equipped with empty position for pressure block one to pop out at corresponding pull line station, by changing the structure of jig, and cooperate pressure plate one is realized in moving process to data line compression fixed prevents the condition of material and deviation, improve the stability of production;And for pull line station, empty position is set on pressure plate one, jig can be data line loosened, to realize pull line operation, continue to move forward after completion will be again with pressure plate one and touch downward rotation data line compression tightly.

Description

Technical Field

[0001] This utility model belongs to the technical field of data cable welding equipment, specifically a data cable welding equipment for preventing misalignment. Background Technology

[0002] Common connectors include USB connectors, Type-C connectors, and iPhone connectors. Connector plugs typically consist of terminals and multiple wires. Existing technology has many devices for connecting and soldering these connectors and data cables together, such as the publicly available technical document "CN 107800016 A, A Flow-Type Automatic Connector Wire Soldering Machine." However, the fixture in this machine lacks a structure to secure the data cable. During movement, external factors may cause the data cable to detach from the fixture, affecting subsequent processing steps.

[0003] In addition, the above technical solutions require pulling, cutting and stripping the data cable, and these actions all require independent mechanisms to complete. This results in a very low overall device size and a large space occupation, which limits the further miniaturization of the device. Utility Model Content

[0004] The purpose of this invention is to provide a data cable soldering device to prevent misalignment, so as to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] A data cable welding device for preventing misalignment includes a conveying mechanism on which a plurality of fixtures are installed. The fixtures sequentially reach a wire pulling station, a cutting station, a wire stripping station, and a welding station. A welding seat is provided at the alignment welding station, and a connector feeding mechanism is correspondingly installed on the welding seat.

[0007] The fixture includes a fixture body, a wire feeding groove on the fixture body, a wire clamping fork at the end of the wire feeding groove, a pressure block rotatably connected to the fixture body, a torsion spring at the rotatable connection, and a pressure plate above the moving channel of the conveying mechanism. The pressure plate is used to press the pressure block, and the pressure plate has a clearance space at the wire pulling position for the pressure block to pop out.

[0008] Further technical solutions also include a front-end processing mechanism for performing wire pulling, cutting, and stripping operations.

[0009] In a further technical solution, the front-end processing mechanism includes a fixed plate, a push-pull assembly is mounted on the fixed plate, a slide is mounted on the output end of the push-pull assembly, and the slide is slidably connected to the fixed plate;

[0010] The upper and lower ends of the slide are respectively equipped with cylinder one and cylinder two. The output ends of cylinder one and cylinder two are respectively equipped with moving plate one and moving plate two. The moving plate one and moving plate two are respectively provided with an upper pull plate, a lower pull plate, an upper cutter and a lower cutter.

[0011] A fixed base is also installed on the lower movable plate. A lower wire stripper is installed at the lower end of the fixed base. A cylinder is installed on the fixed base. An upper wire stripper is installed at the output end of the cylinder through a connector.

[0012] A further technical solution also includes a fixing frame, on which cylinder four and cylinder five are respectively installed at the wire stripping station and the welding station. A connector two is installed at the output end of cylinder four, and a vertically arranged pressure plate two is installed on the connector two. The pressure plate two can extend into the front end of the wire feeding groove to press the data cable tightly.

[0013] The output end of cylinder five is equipped with connector three, and connector three is provided with clamping fork two, which can be staggered in front of clamping fork one.

[0014] In a further technical solution, the feeding mechanism includes a fixed base two and a pushing cylinder. The fixed base two is provided with a pushing channel, which has three openings. One opening is connected to a feeding slide, and the second opening corresponds to a welding seat. The welding seat can be separated from the fixed base two. The output end of the pushing cylinder is connected to a push rod, which passes through another opening.

[0015] In a further technical solution, the welding station includes a translation component and a welding component. A lifting component is installed on the moving end of the translation component, and a welding seat is installed on the moving end of the lifting component. With the cooperation of the translation component and the lifting component, the welding seat moves in an "L" shaped trajectory.

[0016] In a further technical solution, the lifting assembly and the feeding assembly are arranged side by side, the welding seat includes a horizontally arranged base, the base is provided with a feeding channel, limit blocks are symmetrically arranged on both sides of the feeding channel, a pressure block two is rotatably connected between the two limit blocks, a torsion spring is provided at the rotatable connection, and the feeding channel protrudes from the pressure block two to form a welding position.

[0017] In a further technical solution, the front end of the base is provided with two positioning blocks, and a snap-fit ​​position is formed between the two positioning blocks. The clamping fork protrudes from the fixture body and can enter the snap-fit ​​position.

[0018] In a further technical solution, the lifting assembly includes a connecting seat, on the upper and lower parts of which a sensor and a lifting cylinder are respectively installed. A connecting block is installed at the output end of the lifting cylinder. The connecting block is slidably connected to the connecting seat, and the upper surface of the connecting block corresponds to the sensor.

[0019] In a further technical solution, the welding assembly is mounted on the moving end of the translation assembly. The welding assembly includes a longitudinally arranged moving component. A bracket is mounted on the moving end of the moving component, and a welding pen is mounted on the bracket. The end of the welding pen corresponds to the welding position.

[0020] The beneficial effects of this utility model are:

[0021] This invention improves production stability by changing the structure of the fixture and using a pressure plate to press and fix the data cable during movement to prevent material slippage and misalignment. Furthermore, a clearance is provided on the pressure plate for the cable pulling station, allowing the fixture to loosen the data cable for pulling. After pulling, the fixture continues to move forward and will again contact the pressure plate and rotate downward to press the data cable.

[0022] In addition, the jig is in the normally open state under the action of the torsion spring. It will only press the data cable when it comes into contact with the pressure plate. After the welding process is completed, the jig will loosen the data cable as soon as it falls off the pressure plate. At this time, the data cable can be cut into the material, which is very convenient.

[0023] Other features and advantages of this invention will be described in detail in the following detailed description section. Attached Figure Description

[0024] Figure 1 : A three-dimensional structural diagram of this utility model.

[0025] Figure 2 The conveying mechanism and fixture structure of this utility model Figure 1 .

[0026] Figure 3 This utility model Figure 2 Enlarged view of part A.

[0027] Figure 4 The conveying mechanism and fixture structure of this utility model Figure 2 .

[0028] Figure 5 The front-end processing mechanism structure of this utility model Figure 1 .

[0029] Figure 6 The front-end processing mechanism structure of this utility model Figure 2 .

[0030] Figure 7 The present invention relates to the structure of the feeding mechanism, lifting assembly, translation assembly, and welding assembly. Figure 1 .

[0031] Figure 8The present invention relates to the structure of the feeding mechanism, lifting assembly, translation assembly, and welding assembly. Figure 2 .

[0032] Figure 9 The welding seat structure of this utility model Figure 1 .

[0033] Figure 10 The welding seat structure of this utility model Figure 2 .

[0034] Reference numerals: 1-Feeding mechanism, 11-Fixed seat II, 12-Pushing cylinder, 13-Pushing channel, 14-Feeding slide, 15-Push rod, 2-Translation component, 3-Welding component, 31-Moving component, 32-Bracket, 33-Welding pen, 4-Lifting component, 41-Connecting seat, 42-Sensor, 43-Lifting cylinder, 44-Connecting block, 5-Welding seat, 51-Base, 52-Feeding channel, 53-Limiting block, 54-Pressure block II, 55-Welding position, 56-Positioning block, 6-Conveying mechanism, 61-Pressure plate I, 62-Avoidance position, 7-Jig, 71-Jig body, 72-Paying groove 73-Wire clamping fork one, 74-Pressure block one, 8-Front-end processing mechanism, 81-Fixing plate, 82-Push-pull assembly, 83-Slide seat, 841-Cylinder one, 842-Moving plate one, 843-Cylinder two, 844-Moving plate two, 851-Upper pull-up plate, 852-Lower pull-up plate, 853-Upper cutter, 854-Lower cutter, 861-Fixing seat one, 862-Lower wire stripper, 863-Cylinder three, 864-Connector one, 865-Upper wire stripper, 91-Fixing frame, 92-Cylinder four, 93-Cylinder five, 94-Connector two, 95-Pressure plate two, 96-Connector three, 97-Wire clamping fork two. Detailed Implementation

[0035] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.

[0036] Please refer to Figure 1-10 ;

[0037] The welding equipment described in this utility model is designed to fix data cables during the production process to prevent them from falling off or becoming misaligned, which could affect normal production or the yield rate of the products. Specifically, it includes a conveying mechanism 6, on which several fixtures 7 are installed. The fixtures 7 sequentially reach the wire pulling station, the cutting station, the wire stripping station, and the welding station. A welding seat 5 is provided at the alignment welding station, and a connector feeding mechanism 1 is installed on the welding seat 5. It should be noted that the wire pulling station, the cutting station, the wire stripping station, and the welding station should have corresponding devices to complete the corresponding operations. In this embodiment, the structure is not limited, as long as the corresponding function is achieved. For specific details, please refer to the relevant structure of the published technical document "CN 107800016 A, A Flow-Type Automatic Wire Bonding Machine for Connectors".

[0038] Further explanation of fixture 7 includes fixture body 71, with a wire feeding groove 72 on fixture body 71 and a wire clamping fork 73 at the end of wire feeding groove 72. A pressure block 74 is rotatably connected to fixture body 71, and a torsion spring is located at the rotatable connection. Normally, fixture 7 is in a normally open state under the action of the torsion spring, allowing the data cable to be placed in the wire feeding groove 72. Before this, the outer sheath of the data cable has been removed, exposing the inner wires. Several wires are placed separately in the wire clamping fork 73, and then sequentially reach each workstation under the drive of conveying mechanism 6. Preferably, even though fixture 7 is in a normally open state, the pressure block is still tilted towards fixture body 71. A pressure plate 61 is located above the moving channel of conveying mechanism 6. After fixture 7 carries the data cable into the production process, the pressure plate 61 of pressure block 74 rotates downwards under the pressure of pressure, pressing the data cable in wire feeding groove 72. 1. Since the pressure block 74 runs through every processing station, it can continuously press and fix the data cable. Preferably, a soft rubber pad is provided on the bottom surface of the pressure block to prevent damage to the outer sheath of the data cable. In addition, the cable pulling station requires the data cable to be pulled forward, at which time the data cable cannot be fixed. Therefore, a special setting is made for the cable pulling station. The pressure plate 61 is provided with a clearance 62 corresponding to the cable pulling station. When the fixture 7 reaches the cable pulling station, the pressure block 74 is exactly aligned with the clearance 62. At this time, the pressure block 74 has room to move and pops up under the action of the torsion spring to unlock and release the data cable. After the cable pulling operation is completed, the fixture 7 continues to move forward under the action of the conveying mechanism 6. The pressure block 74 disengages from the clearance 62 and will once again come into contact with the pressure plate 61 and rotate downward to press the data cable. Through the above design, it can be ensured that the data cable is pressed and fixed during the movement process, avoiding situations such as falling off and misalignment, and improving the stability of production.

[0039] To further reduce the size of the equipment, the wire pulling, cutting and stripping operations are all completed by the front-end processing mechanism 8. The wire pulling, cutting and stripping operations have a common feature: they are also up-and-down closing and back-and-forth movement. Based on this common feature, they are integrated together. Specifically, it includes a fixed plate 81, on which a push-pull assembly 82 is installed. A slide 83 is installed at the output end of the push-pull assembly 82, and the slide 83 is slidably connected to the fixed plate 81.

[0040] Cylinder 1 841 and Cylinder 2 843 are respectively mounted opposite each other at the upper and lower ends of the slide 83. Movable plate 1 842 and Movable plate 2 844 are respectively mounted on the output ends of cylinder 1 841 and Cylinder 2 843. Movable plate 1 842 and Movable plate 2 844 are respectively equipped with an upper pull plate 851, a lower pull plate 852, an upper cutter 853, and a lower cutter 854. It should be noted that pulling the wire only requires clamping it, while cutting the wire requires it to drop lower and cross over to cut it. The upper and lower cutting blades 854 and the upper and lower wire pulling plates 852 move up and down synchronously, so their height difference or shape will be adjusted accordingly. For more precise wire stripping, a separate power unit is provided. Specifically, a fixed base 861 is installed on the lower moving plate. The lower wire stripper 862 is installed at the lower end of the fixed base 861. A cylinder 863 is installed on the fixed base 861. The upper wire stripper 865 is installed at the output end of the cylinder 863 through a connector 864.

[0041] Because several jigs 7 enter like an assembly line under the drive of the conveyor mechanism 6, each subsequent station is a further processing of the previous station, enabling synchronous action. Assume there are three jigs 7 corresponding to the wire pulling station, cutting station, and wire stripping station respectively. During operation, the pushing assembly first pushes the slide block 83 towards the conveyor mechanism 6, allowing the wire in each jig 7 to enter the corresponding station. Then, cylinders 841 and 843 actuate, causing moving plates 842 and 844 to move closer together, simultaneously pulling up the wire plate 8. 51 and pull-down plate 852 clamp the wire at the first station, upper cutter 853 and lower cutter 854 cut the wire at the second station, then cylinder 863 in the third station moves the upper wire stripper 865 and lower wire stripper 862 downwards and clamps the wire together; finally, push-pull assembly 82 pulls slide 83 backwards, causing the whole assembly to move backwards. After the upper pull-down plate 851 and pull-down plate 852 clamp the wire, they are pulled, and the upper wire stripper 865 and lower wire stripper 862 clamp the wire, stripping the outer layer of the wire during the backward movement.

[0042] Based on the above structure, the three actions can be performed simultaneously, which not only further reduces the size but also improves work efficiency.

[0043] Furthermore, additional fixing structures are provided for the wire stripping and soldering stations, specifically including a fixing frame 91. The fixing frame 91 is equipped with cylinder 4 92 and cylinder 5 93 respectively at the wire stripping and soldering stations. A connector 2 94 is installed at the output end of cylinder 4 92. A vertically set pressure plate 2 95 is installed on the connector 2 94. Before wire stripping, the pressure plate 2 95 is pushed out by cylinder 4 92 and inserted into the front end of the wire feeding groove 72 to press the data cable tightly, so as to avoid pulling the data cable during the wire stripping process. A connector 3 96 is installed at the output end of cylinder 5 93. A wire clamping fork 2 97 is provided on the connector 3 96. The wire clamping fork 2 97 can be staggered in front of the wire clamping fork 1 73 to separate and press down the wire so that it can better contact the connector.

[0044] One embodiment of the feeding mechanism 1 of this utility model specifically includes a fixed base 11 and a pushing cylinder 12. The fixed base 11 is provided with a pushing channel 13, which has three openings, specifically in a "T" shape. One opening is connected to a feeding slide 14, and the other end of the feeding slide 14 can be connected to a vibratory feeder or other components for outputting connectors. The second opening corresponds to the welding seat 5, which can be separated from the fixed base 11. The output end of the pushing cylinder 12 is connected to a push rod 15, which passes through another opening. During operation, a connector is fed into the pushing channel 13 through the feeding slide 14. Then, the pushing cylinder 12 is activated to insert the push rod 15 into the pushing channel 13, while simultaneously pushing the connector toward the welding seat 5, and finally into the welding position 55 of the welding seat 5.

[0045] In this utility model, the welding station includes a translation component 2 and a welding component 3. A lifting component 4 is installed on the moving end of the translation component 2, and a welding seat 5 is installed on the moving end of the lifting component 4. The welding seat 5 corresponds to the output end of the feeding mechanism 1. The mechanism described in this utility model is applied in the whole machine equipment, so there should be a data cable fixing mechanism in front of the mechanism. During operation, one of the connectors is output to the welding seat 5 through the feeding mechanism 1. At this time, the welding seat 5 is in a state away from the data cable, and the welding seat 5 and the data cable are vertically offset. Then, the translation component 2 first drives the welding seat 5 to move laterally, so that the welding seat 5 is below the data cable, and the connector in the welding seat 5 corresponds to the wire in the data cable. Then, the lifting component 4 drives the welding seat 5 to rise, so that the connector is close to the wire. Of course, the wires are pre-separated and will not overlap. Then, the welding component 3 welds the wire and the connector together.

[0046] It should be noted that the data cable needs to undergo stripping and oiling before soldering, which may cause the wire to bend. If the connector is moved in the front, it will come into contact with the bent wire and the soldering cannot be completed. This utility model, through the cooperation of the translation component 2 and the lifting component 4, makes the soldering seat 5 move in an "L" shaped trajectory, which can avoid the front contact between the connector and the wire. Even if the wire is bent, the soldering point in the connector can still be aligned with the wire and the soldering can be completed, eliminating the problem of missing core soldering and improving the yield rate.

[0047] In this invention, the lifting assembly 4 and the feeding mechanism 1 are arranged side by side, which greatly reduces space occupation. Furthermore, the welding base 5 includes a horizontally arranged base 51, which is connected to the lifting assembly 4 and extends across the feeding mechanism 1. The base 51 has a feeding channel 52, with limit blocks 53 symmetrically arranged on both sides of the feeding channel 52. A pressure block 54 is rotatably connected between the two limit blocks 53, and a torsion spring is provided at the rotatable connection. The feeding channel 52 protrudes beyond the pressure block 54 to form a welding position 55. That is, the length of the feeding channel 52 is greater than the length of the pressure block 54. In the initial state, the pressure block 54 is drooping under the action of the torsion spring, and at the same time, it blocks the feeding channel 52. After the connector enters from the feeding channel 52, it will push the pressure block 54 up and make it rotate. However, under the action of the torsion spring, the pressure block 54 applies pressure to the upper surface of the connector to prevent it from jumping. With the push rod 15 advancing, the soldering end of the connector will reach the soldering position 55 and be exposed. However, at this time, the pressure block 54 still presses part of the connector tightly.

[0048] Preferably, the front end of the base 51 is provided with two positioning blocks 56, and a snap-fit ​​position is formed between the two positioning blocks 56. The clamping fork 73 protrudes from the fixture body 71 and can enter the snap-fit ​​position. The positioning blocks 56 can prevent the welding seat 5 from shaking and causing misalignment, thereby improving the accuracy of welding.

[0049] One embodiment of the present invention relates to a lifting assembly 4, specifically including a connecting base 41, with a sensor 42 and a lifting cylinder 43 respectively mounted on the upper and lower parts of the connecting base 41. A connecting block 44 is mounted on the output end of the lifting cylinder 43, and the connecting block 44 is slidably connected to the connecting base 41. The upper end surface of the connecting block 44 corresponds to the sensor 42. A welding seat 5 is connected to the connecting block 44. The lifting cylinder 43 causes the connecting block 44 to move up and down, synchronously driving the welding seat 5 to move. The sensor 42 detects the distance the connecting block 44 moves, thereby improving the moving accuracy.

[0050] In this embodiment of the utility model, the welding component 3 is installed on the moving end of the translation component 2, that is, the welding component 3, the lifting component 4, and the welding seat 5 move synchronously, which can limit the position between the welding component 3 and the welding seat 5. In other words, the welding component 3 only needs to move up and down to complete the welding operation, which reduces unnecessary movements, makes the welding process simpler, and improves work efficiency.

[0051] Furthermore, the translation component 2 includes a fixed base 11, on which a movable plate is slidably connected and a push cylinder is installed. The output end of the push cylinder is connected to the movable plate. A connecting seat 41 is installed at the front end of the movable plate. The welding component 3 is installed on the movable plate. The welding component 3 includes a longitudinally arranged moving component 31. A bracket 32 ​​is installed at the moving end of the moving component 31. A welding pen 33 is installed on the bracket 32. The end of the welding pen 33 corresponds to the welding position 55.

[0052] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0053] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style of the specification is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A data cable welding device for preventing misalignment, comprising a conveying mechanism (6), wherein a plurality of fixtures (7) are mounted on the conveying mechanism (6), the fixtures (7) sequentially reach a wire pulling station, a cutting station, a wire stripping station, and a welding station, wherein a welding seat (5) is provided at the alignment welding station, and a connector feeding mechanism (1) is correspondingly mounted on the welding seat (5), characterized in that: The fixture (7) includes a fixture body (71), a wire feeding groove (72) is provided on the fixture body (71), a wire clamping fork (73) is provided at the end of the wire feeding groove (72), a pressure block (74) is rotatably connected to the fixture body (71), a torsion spring is provided at the rotatable connection, and a pressure plate (61) is provided above the moving channel of the conveying mechanism (6). The pressure plate (61) is used to press the pressure block (74) tightly. The pressure plate (61) is provided with a clearance position (62) at the wire pulling position for the pressure block (74) to pop out.

2. The anti-misalignment data cable welding equipment according to claim 1, characterized in that: It also includes a front-end processing mechanism (8) for completing wire pulling, cutting and stripping operations.

3. The anti-misalignment data cable welding equipment according to claim 2, characterized in that: The front-end processing mechanism (8) includes a fixed plate (81), a push-pull assembly (82) is installed on the fixed plate (81), a slide (83) is installed at the output end of the push-pull assembly (82), and the slide (83) is slidably connected to the fixed plate (81). The upper and lower ends of the slide (83) are respectively equipped with cylinder one (841) and cylinder two (843). The output ends of cylinder one (841) and cylinder two (843) are respectively equipped with moving plate one (842) and moving plate two (844). The moving plate one (842) and moving plate two (844) are respectively provided with upper pull plate (851), lower pull plate (852), upper cutter (853) and lower cutter (854). A fixed base (861) is also installed on the lower movable plate. A lower wire stripper (862) is installed at the lower end of the fixed base (861). A cylinder (863) is installed on the fixed base (861). An upper wire stripper (865) is installed at the output end of the cylinder (863) through a connector (864).

4. The anti-misalignment data cable welding equipment according to claim 1, characterized in that: It also includes a fixing frame (91), on which cylinder four (92) and cylinder five (93) are respectively installed at the wire stripping station and the welding station. A connector two (94) is installed at the output end of cylinder four (92), and a vertically arranged pressure plate two (95) is installed on the connector two (94). The pressure plate two (95) can extend into the front end of the wire feeding groove (72) to press the data cable tightly. The output end of cylinder five (93) is equipped with connector three (96), and connector three (96) is provided with clamping fork two (97), which can be staggered in front of clamping fork one (73).

5. The anti-misalignment data cable welding equipment according to claim 1, characterized in that: The feeding mechanism (1) includes a fixed base (11) and a pushing cylinder (12). The fixed base (11) is provided with a pushing channel (13). The pushing channel (13) has three openings. One of the openings is connected to a feeding slide (14), and the second opening corresponds to a welding seat (5). The welding seat (5) can be separated from the fixed base (11). The output end of the pushing cylinder (12) is connected to a push rod (15), and the push rod (15) passes through another opening.

6. A data cable soldering device for preventing misalignment according to claim 1 or 5, characterized in that: The welding station includes a translation component (2) and a welding component (3). A lifting component (4) is installed on the moving end of the translation component (2). A welding seat (5) is installed on the moving end of the lifting component (4). With the cooperation of the translation component (2) and the lifting component (4), the welding seat (5) moves in an "L" shaped trajectory.

7. The anti-misalignment data cable welding equipment according to claim 6, characterized in that: The lifting assembly (4) and the feeding assembly are arranged side by side. The welding seat (5) includes a horizontally arranged base (51). The base (51) is provided with a feeding channel (52). Limiting blocks (53) are symmetrically arranged on both sides of the feeding channel (52). A pressure block (54) is rotatably connected between the two limiting blocks (53). A torsion spring is provided at the rotatable connection. The feeding channel (52) protrudes from the pressure block (54) to form a welding position (55).

8. The anti-misalignment data cable welding equipment according to claim 7, characterized in that: The front end of the base (51) is provided with two positioning blocks (56), and a snap-fit ​​position is formed between the two positioning blocks (56). The clamping fork (73) protrudes from the fixture body (71) and can enter the snap-fit ​​position.

9. The anti-misalignment data cable welding equipment according to claim 6, characterized in that: The lifting assembly (4) includes a connecting seat (41), on which a sensor (42) and a lifting cylinder (43) are respectively installed. A connecting block (44) is installed at the output end of the lifting cylinder (43). The connecting block (44) is slidably connected to the connecting seat (41), and the upper end face of the connecting block (44) corresponds to the sensor (42).

10. The anti-misalignment data cable welding equipment according to claim 6, characterized in that: The welding assembly (3) is installed on the moving end of the translation assembly (2). The welding assembly (3) includes a longitudinally arranged moving assembly (31). A bracket (32) is installed on the moving end of the moving assembly (31). A welding pen (33) is installed on the bracket (32). The end of the welding pen (33) corresponds to the welding position (55).

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